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ORIGINAL ARTICLE
doi:10.1111/evo.12897
Partially repeatable genetic basis of benthicadaptation in threespine sticklebacksPriscilla A. Erickson,1 Andrew M. Glazer,1 Emily E. Killingbeck,1 Rachel M. Agoglia,1 Jiyeon Baek,1
Sara M. Carsanaro,1 Anthony M. Lee,1 Phillip A. Cleves,1 Dolph Schluter,2 and Craig T. Miller1,3
1Department of Molecular and Cell Biology, University of California, Berkeley, California, 947202Biodiversity Research Centre and Zoology Department, University of British Columbia, Vancouver, British Columbia,
Canada3E-mail: [email protected]
Received July 6, 2015
Accepted February 23, 2016
The extent to which convergent adaptation to similar ecological niches occurs by a predictable genetic basis remains a fundamental
question in biology. Threespine stickleback fish have undergone an adaptive radiation in which ancestral oceanic populations
repeatedly colonized and adapted to freshwater habitats. In multiple lakes in British Columbia, two different freshwater ecotypes
have evolved: a deep-bodied benthic form adapted to forage near the lake substrate, and a narrow-bodied limnetic form adapted
to forage in open water. Here, we use genome-wide linkage mapping in marine × benthic F2 genetic crosses to test the extent
of shared genomic regions underlying benthic adaptation in three benthic populations. We identify at least 100 Quantitative Trait
Loci (QTL) harboring genes influencing skeletal morphology. The majority of QTL (57%) are unique to one cross. However, four
genomic regions affecting eight craniofacial and armor phenotypes are found in all three benthic populations. We find that QTL
are clustered in the genome and overlapping QTL regions are enriched for genomic signatures of natural selection. These findings
suggest that benthic adaptation has occurred via both parallel and nonparallel genetic changes.
KEY WORDS: Convergent evolution, genotyping-by-sequencing, parallel evolution, QTL, skeleton.
Convergent evolution, the evolution of similar phenotypes in inde-
pendent lineages adapting to similar ecological niches, provides
compelling evidence for ecological adaptation (Schluter 2000), as
well as natural replicates to study the genetic basis of evolution-
ary change. Convergent phenotypic evolution sometimes occurs
through changes in the same genes in multiple lineages, called par-
allel evolution (Stern 2013), suggesting some evolutionary trajec-
tories are constrained and partially predictable. How often conver-
gent evolution occurs through parallel and thus predictable genetic
changes remains an outstanding and important question (Stern
and Orgogozo 2008, 2009; Rosenblum et al. 2014). While many
studies have identified similar genetic bases for convergent pheno-
types (reviewed in Conte et al. 2012; Stern 2013), few studies have
simultaneously tested for genetic parallelism underlying many
phenotypic traits in multiple convergently evolved populations.
All data are available in the Supplemental Data File.
One critical first step in testing for a parallel genetic basis
of convergence is mapping the genomic regions involved in con-
vergent phenotypic evolution. Although quantitative trait locus
(QTL) mapping can robustly identify genomic regions underly-
ing complex traits, the genomic intervals are typically large and
contain multiple genes when there are few rounds of recombi-
nation in the genetic cross. However, comparing the genomic
intervals of QTL between crosses from different populations will
either support or refute the hypothesis of genetic parallelism, since
QTL can either map to overlapping regions (potentially parallel)
or map to nonoverlapping regions (nonparallel).
Threespine stickleback fish (Gasterosteus aculeatus) pro-
vide a powerful vertebrate model system to study convergent
phenotypic evolution, as ancestral oceanic forms have repeat-
edly colonized and rapidly adapted to countless freshwater
environments throughout the Northern hemisphere (Bell and
Foster 1994). Many morphological phenotypes convergently
1C© 2016 The Author(s).Evolution
PRISCILLA A. ERICKSON ET AL.
evolve in freshwater, most of which are likely adaptations to the
new ecological pressures in freshwater environments, such as a
different diet and predation regime. In five drainages in British
Columbia, two freshwater species pairs convergently evolved: a
benthic species adapted to feed on the lake bottom, and a limnetic
species adapted to forage in the open water (McPhail 1984, 1992;
Schluter and McPhail 1992). Across lakes, the different benthic
and limnetic forms strikingly resemble each other, yet evolved
in isolation (Taylor and McPhail 1999). Once thought to be the
result of sympatric speciation, phylogenetic analyses based on
allozymes (McPhail 1984, 1992), nuclear microsatellites (Tay-
lor and McPhail 2000), mtDNA haplotypes (Taylor and McPhail
1999), genome-wide SNP genotypes (Jones et al. 2012a), and
salinity tolerance experiments (Kassen et al. 1995) instead sup-
port a double invasion scenario. In this scenario, the first oceanic
colonization event evolved into a freshwater form, and then a
second oceanic colonization event displaced the first population
to the benthic niche while adapting to the alternative open water
limnetic niche (Taylor and McPhail 2000). Thus, the distinct ben-
thic morphs found in species pair lakes are especially divergent
from marine ancestors and offer an outstanding system to study
the genetic architecture of repeatedly but independently evolved
phenotypes.
Differences in a number of skeletal traits have evolved repeat-
edly in benthic sticklebacks. Benthic fish have fewer gill rakers, a
larger jaw, and reduced pelvic and dorsal spines (McPhail 1984,
1992, 1994; Schluter and McPhail 1992). Additionally, benthic
fish from at least one of these species pair lakes, Paxton Lake,
have evolved more pharyngeal teeth and longer branchial bones
relative to marine fish (Cleves et al. 2014; Erickson et al. 2014).
Collectively, these craniofacial differences have important func-
tional consequences: benthic fish are more efficient at foraging
for larger prey items in a benthic substrate, and limnetic fish are
more efficient at foraging for plankton from open water (Bentzen
and McPhail 1984; Schluter 1993). In turn, the distinct morpholo-
gies are important for survival in their respective niches; benthic-
limnetic hybrids have reduced survival in nature (Gow et al. 2007).
Some of these benthic trophic traits have also been documented
in nearby lakes that have a predominantly benthic environment
yet only have a single ecomorph (Lavin and Mcphail 1985), sug-
gesting that many of these traits are important for adaptation to a
benthic environment, either with or without a limnetic ecomorph.
How often do the same genomic regions underlie conver-
gent phenotypic adaptation in multiple benthic environments?
Hybridization occurs between anadromous marine and freshwa-
ter sticklebacks (Hagen 1967; Jones et al. 2006, 2008), and likely
maintains freshwater-adapted alleles at low frequency in oceanic
populations (Barrett and Schluter 2008; Schluter and Conte 2009;
Hohenlohe et al. 2012; Jones et al. 2012b; Terekhanova et al.
2014), which might increase the chances of parallel evolution. For
example, an ancient allele of Eda conferring reduced lateral plate
armor is present at low frequency in marine populations and has
been reused many times in freshwater adaptation (Colosimo et al.
2004, 2005; O’Brown et al. 2015). Allele sharing by hybridization
of differently adapted populations has also been found to be an
important contributor to parallel evolution in other species, includ-
ing Heliconius butterflies, Galapagos finches, mice, humans, and
Mimulus (The Heliconius Genome Consortium 2012; Lamich-
haney et al. 2015; Song et al. 2011; Huerta-Sanchez et al. 2014;
Stankowski and Streisfeld 2015). However, convergent evolution
by novel mutations in the same gene or genetic pathway has also
been observed in sticklebacks and other systems (Colosimo et al.
2004; Protas et al. 2006; Kingsley et al. 2009; Chan et al. 2010;
Rosenblum et al. 2010; Vickrey et al. 2015). Alternatively, con-
vergent phenotypic evolution may have a mostly different (non-
parallel) genetic basis (Wittkopp et al. 2003; Kowalko et al. 2013;
Ellis et al. 2015; Glazer et al. 2015). The overall extent to which
parallel versus nonparallel genetic changes and new mutations
versus standing variation are involved in stickleback evolution
remains largely unknown (Conte et al. 2015).
Here, we use genome-wide linkage mapping to map QTL
influencing a variety of trophic and armor traits in three marine
× benthic F2 genetic crosses, each using a benthic grandmother
from independently derived benthic populations in Paxton, Priest,
and Enos Lakes. The shared marine grandfather individual came
from an anadromous marine population geographically near the
benthic populations (Little Campbell River, BC), and thus serves
as an extant proxy for the marine population that likely colonized
the lakes. This crossing scheme allows identification of genomic
regions responsible for phenotypic differentiation of each benthic
population compared to a shared marine genetic background. In
the three crosses, QTL that map to overlapping genomic regions
and influence similar phenotypes in multiple crosses are candi-
dates for parallel genetic evolution. Alternatively, and assuming
no major chromosomal rearrangements, QTL mapping to unique
genomic regions indicate nonparallel evolution.
MethodsANIMAL STATEMENT AND CROSSES
A single wild Little Campbell marine (LCM, Little Campbell
River, British Columbia) male was crossed to wild benthic fresh-
water females from Paxton Lake (PAXB, Texada Island, BC),
Priest Lake (PRIB, Texada Island, BC), and Enos Lake (ENOB,
Vancouver Island, BC) in 2002. See Figure 1A for representa-
tive fish from each population and maps of population locations
(Fig. 1B and C). Since the Enos species pair collapsed between
1994 and 2002 (Kraak et al. 2001; Taylor et al. 2006), a fe-
male from Enos lake that morphologically resembled the benthic
ecomorph was used. Fish were raised in 100 l aquaria in 5 ppt
2 EVOLUTION 2016
REPEATABLE EVOLUTION IN BENTHIC STICKLEBACKS
Figure 1. Benthic populations studied. (A) Representative wild-caught adult fish from each population, with bone stained with Alizarin
red. LCM = Little Campbell Marine, PAXB = Paxton Benthic, PRIB = Priest Benthic, ENOB = Enos Benthic. (B, C) Location of the marine
population source and three species-pair lakes in the Pacific Northwest. The Little Campbell River, where the anadromous LCM population
breeds, is indicated with an arrow in (B).
saltwater. F1 fish were intercrossed to produce a total of five F2
families (see Table S1). One family of 180 F2s was studied for the
ENOB cross; 186 F2s (two families of 94 and 92) for the PAXB
cross, and 180 F2s (two families of 90) for the PRIB cross. F2s
were raised to six months, euthanized, and stored in ethanol. All
animal work was approved by the UBC Animal Care committee
under protocol A00-191.
GENOTYPING, PHENOTYPING, LINKAGE MAP
CONSTRUCTION, AND QTL MAPPING
Thirty-six skeletal phenotypes in ten trait categories (Fig. S1,
Table S2) were measured in F2s as previously described (Miller
et al. 2014) and corrected for standard length and sex when ap-
propriate. DNA was extracted from pectoral fins, F2s genotyped
using Genotyping by Sequencing (GBS) in two Illumina HiSeq
2000 lanes using 384 barcoded samples per lane, and sequence
reads analyzed using a custom pipeline based on SNPs with op-
posite homozygous genotypes in the grandparents as described in
Glazer et al. 2015 (Table S3). Linkage maps based on 805 binned
markers shared in all three crosses were constructed in JoinMap
4.0 (Kyazma). The stepwiseqtl, addqtl, refineqtl, and fitqtl func-
tions of R/qtl were used to identify QTL significant at a genome-
wide significance level of LOD = 3.7. See Supporting Online Ma-
terial for additional genotyping, phenotyping, and QTL mapping
methods.
For analysis of phenotypic variation at specific markers, the
argmax.geno function of R/qtl was used to calculate the most
likely genotype for fish with missing genotypes at that marker.
Dominance and additivity of each QTL were calculated based on
the phenotypic means for each genotypic class at the peak marker
(Falconer and Mackay 1996). In the PAXB cross only, a subset
of F2s lacking pelvic spines were excluded from the analysis of
pelvic spine length. In this cross, pelvic spine presence/absence
was mapped separately as a binary trait with the scanone
function.
IDENTIFYING SUGGESTIVE PARALLEL QTL
The minimum QTL effect size that can be detected is larger when
cross size is smaller (Beavis 1998), so detecting small effect QTL
shared in multiple relatively small crosses is even less likely. To
minimize the resulting bias against detecting parallelism, espe-
cially given the limitations of the cross sizes of �180 F2s per
each of three crosses studied here, we considered QTL identi-
fied in the genome-wide search to be “candidate” QTL for each
trait class (as in Conte et al. 2015). If no QTL for the same trait
class were found on the same chromosome on which the can-
didate QTL was detected in a second cross, we then looked for
suggestive parallel QTL that overlapped the candidate QTL as
follows. We tested for QTL having LOD scores above 2.0 on the
same chromosome for all phenotypes in the same trait class in the
EVOLUTION 2016 3
PRISCILLA A. ERICKSON ET AL.
second cross. We then added these QTL to the refineqtl model to
recalculate the LOD scores and 1.5 LOD intervals for the QTL
model. If the peak marker of the suggestive QTL was found within
the 1.5 LOD interval of any candidate QTL in the same trait class
from either of the other two crosses, we considered the QTL to
be a suggestive parallel QTL and included it in the supplemental
analysis of suggestive QTL. QTL that did not meet this criterion
were removed. All analyses involving suggestive parallel QTL
used the QTL locations and percentage of phenotypic variance
explained (PVEs) estimated by the refineqtl model that included
suggestive parallel QTL.
QTL FILTERING
To minimize overcounting QTL for multiple similar phenotypes
within a trait class, we generated a list of filtered QTL as follows.
For each of the seven trait classes with multiple phenotypes (teeth,
gill rakers, branchial bones, median fin, pelvic spines, jaw, and
opercle), we identified the largest effect QTL (highest PVE) on
each chromosome for that trait category in each cross. Since many
of the phenotypes measured are serially repeated traits (such as
gill raker count or ceratobranchial length), this filtering method
avoids overrepresentation of QTL influencing multiple anatomi-
cally similar traits, following a previous analysis of many stick-
leback skeletal QTL (Miller et al. 2014). The filtering approach
was applied to both genome-wide and suggestive parallel QTL.
Hereafter, unless otherwise specified, QTL refers to these filtered
QTL (Tables S4 and S5).
QTL CLUSTERING
We tested for clustering of QTL as described (Arnegard et al.
2014). Given the total number of QTL detected in each cross, we
calculated the expected number of QTL per chromosome based
on genetic length, physical length, and number of Ensembl gene
predictions per chromosome. Physical length and gene number
were based on the revised assembly of Glazer et al. 2015 and
genetic length was based on the linkage map for each cross. We
then used the R function chisq.test to test whether the observed
number of QTL per chromosome differed significantly from the
expected number. P-values were calculated based on 10,000 per-
mutations of the data. In crosses in which the distribution differed
significantly from the expected number (P < 0.05), we used the
standard residuals from the chi-square test to determine which
chromosomes were enriched for QTL, with a standard residual
>2 considered enriched.
OVERLAP ANALYSIS
We determined overlap by asking whether the physical 1.5 LOD
intervals of QTL for the same trait category overlapped between
crosses. Unique QTL were identified if they did not overlap with
a QTL found in any other cross. Double overlaps were identified
if they overlapped in only two of the three crosses. Triple overlaps
were identified if the 1.5 LOD intervals overlapped a region of
the genome in all three crosses. We calculated the mean PVE
of each double and triple overlap by averaging the individual
PVEs of the overlapping QTL. To test whether the QTL datasets
were enriched for overlapping QTL, we randomly permuted the
physical locations of the QTL in the genome 10,000 times. In
each permutation, no two QTL in the same trait category in the
same cross could have overlapping 1.5 LOD intervals. We then
calculated the number of unique QTL, double overlaps, and triple
overlaps for each permutation. We compared the actual number of
overlaps between crosses to the distribution of simulated number
of overlaps and calculated a P-value for the extent of overlap
based on the percentage of permutations in which the number of
overlaps was equal to or greater than the observed number.
ANALYSIS OF SIGNALS OF SELECTION
Two previous studies identified regions of the stickleback genome
that show strong signatures of natural selection in 21 populations
(Jones et al. 2012b) or in benthic populations relative to their lim-
netic counterparts (Jones et al. 2012a). As in the overlap analysis,
we tested for an enrichment of these signals of selection in the
total set of QTL found here by randomly permuting the locations
of the 1.5 LOD intervals of the QTL 10,000 times for each cross.
We then compared the number of signals of selection overlapping
QTL in the permuted dataset to the number of actual overlaps
with the signals of selection. We calculated fold enrichment for
each cross based on the ratio of the actual number of overlaps
relative to the permuted mean. The P-value was calculated as the
percent of all permutations in which the number of overlaps was
greater than or equal to the observed number of overlaps. For
overlapping double or triple QTL, the maximum physical range
spanned by the 1.5 LOD intervals of all two or three QTL was
used in calculations.
For the genomic regions displaying marine-freshwater sig-
nals of selection in 21 stickleback genome sequences (Jones et al.
2012b), we used the union of the HMM and CSS signals of
selection (a total of 240 regions) and calculated their locations
in the revised genome assembly from Glazer et al. 2015. Each
time the 1.5 LOD interval of a QTL overlapped with a signal
of selection was counted as an overlap. For the benthic-limnetic
signals of selection, we used all 46 FST-outlier SNPs identified
in any one of the three species-pair lakes (Paxton Lake, Priest
Lake, or Quarry Lake; Jones et al. 2012a) and converted the SNP
location to the revised genome assembly (Glazer et al. 2015).
We then counted every overlap between a QTL and an FST-
outlier SNP and compared this number to the simulated number of
overlaps.
4 EVOLUTION 2016
REPEATABLE EVOLUTION IN BENTHIC STICKLEBACKS
ResultsOVERLAPPING REGIONS OF THE GENOME AFFECT
ARMOR AND CRANIOFACIAL TRAITS IN MULTIPLE
BENTHIC POPULATIONS
To test whether similar genetic architectures underlie skeletal
adaptation in multiple populations of benthic sticklebacks, we
phenotyped 36 skeletal traits in ten different trait categories in
three marine × benthic crosses (see Table S2) and found a strong
correlation between phenotypes within each trait category within
each cross (see Fig. S1). We used genotyping-by-sequencing
(GBS, Elshire et al. 2011; Glazer et al. 2015) to generate genome-
wide genotypes with at least a 50% success rate in 546/554
(98.5%) of F2s sequenced (see Table S3). Using random permuta-
tions of 22 phenotypes, we calculated a genome-wide significance
threshold of LOD 3.7 for QTL mapping. All traits except standard
length (SL), basihyal length (BH), and premaxilla length (PML)
mapped significantly to at least one chromosome in at least one
cross with this cutoff. Our linkage maps were all collinear with
the revised genome assembly (Glazer et al. 2015), suggesting
no major genome rearrangements occurred in the parents of the
crosses.
We identified a total of 157 QTL (46 PAXB, 64 PRIB, and 47
ENOB) significantly affecting skeletal traits in the three crosses
(see Fig. 2A, and Table S4). We then filtered the QTL from
each cross such that only the QTL with the highest percentage
of phenotypic variance explained (PVE) in a trait class was kept
for each chromosome to minimize redundant oversampling of
QTL (following Miller et al. 2014). This filtering resulted in a
total of 100 QTL (33 PAXB, 40 PRIB, and 27 ENOB). Overall,
the effect sizes of filtered and unfiltered QTL were quite similar:
most QTL were small effect (PVE < 20), with a few QTL of large
effect (see Fig. S2 for the distribution of PVE of all QTL and
all filtered QTL in each cross). QTL overlapped if the physical
ranges of the 1.5 LOD intervals overlapped in two or three crosses.
We observed that 43% of all filtered QTL overlapped with a
QTL influencing a trait in the same category in at least one other
cross.
We found six overlapping QTL between PAXB and PRIB,
two between PAXB and ENOB, and two between PRIB and
ENOB (Fig. 2B). Ninety percent (9/10) of all QTL overlapping
in two crosses had effects in the same direction. Eight QTL over-
lapped in all three crosses (Figs. 2B, 3, and 4). Five of these
QTL affected armor traits and were found on chromosome 4 (dor-
sal spine length, pelvic spine length, and lateral plate number,
Fig. 3A–C), chromosome 21 (pelvic spine, Fig. 3D), and chro-
mosome 7 (lateral plates, Fig. 3E). Notably, the chromosome 4
QTL affecting dorsal and pelvic spines (Fig. 3A and B) had large
effects in all three crosses and mapped to a similar region of chro-
mosome 4 in all three crosses. However, the genetic basis of pelvic
and dorsal spine length are markedly different: several QTL were
identified that affect pelvic but not dorsal spine length (Fig. 2).
For all triple-overlapping armor QTL, the benthic allele conferred
a reduction in the number or size of skeletal element measured,
except for the chromosome 7 lateral plate QTL in PRIB, for which
heterozygotes had the fewest plates (Table S4).
The genetic and developmental bases of several QTL influ-
encing freshwater trophic adaptation in sticklebacks have been
studied extensively (Cleves et al. 2014; Erickson et al. 2014;
Glazer et al. 2014; Ellis et al. 2015). We were particularly inter-
ested in whether previously identified QTL affecting the branchial
skeleton (the major food-processing apparatus in fish) were found
in multiple benthic populations, which could suggest that these
QTL are under selection in benthic environments. A large-effect
QTL increasing ventral pharyngeal tooth gain on chromosome 21
(Miller et al. 2014; Cleves et al. 2014) was indeed found in all
three crosses (Fig. 4A), with the benthic allele conferring more
teeth. However, the PRIB cross appeared to have two QTL peaks
on chromosome 21 (Fig. 4A). We found that a gill raker reduction
QTL on chromosome 4, previously described to overlap in three
independently derived freshwater populations (including PAXB,
Glazer et al. 2014), was also found in all three benthic popu-
lations, as judged by overlapping 1.5 LOD intervals (Fig. 4B).
However, a second previously identified QTL on chromosome
20 was found only in the PAXB and PRIB crosses (Table S8).
Previously described QTL for increased branchial bone length
(Erickson et al. 2014) on chromosomes 4 and 21 were each found
in two crosses but were found in all three crosses when suggestive
parallel QTL were included (Fig. 4C–D). However, the sugges-
tive ENOB chromosome 21 QTL appeared to map to a different
region of the chromosome (although it was counted as an overlap
because the peak marker was found within the 1.5 LOD interval
of the PRIB CB5 QTL, which was in the same branchial bone
trait category). We also found a previously unreported QTL on
chromosome 8 that influenced opercle width in all three crosses
(Fig. 4E).
BENTHIC QTL FOR SIMILAR TRAITS OVERLAP MORE
THAN EXPECTED BY RANDOM CHANCE
We hypothesized that abundant standing genetic variation
(Colosimo et al. 2005; Conte et al. 2012; Bell and Aguirre 2013)
and similar selective pressures in the benthic freshwater environ-
ments would lead to more genetic parallelism in QTL affecting
skeletal traits than expected by chance. To test for significant
parallelism, we randomly permuted the locations of the QTL
in the genome without replacement for each trait category and
calculated the number of overlapping QTL in each permutation
(Fig. 2B, see Fig. S3 for the distributions of simulated overlapping
QTL). We found that the observed number of triple-overlapping
QTL significantly exceeded the number of triple QTL expected
by chance (eight observed triple overlaps vs. a maximum of five
EVOLUTION 2016 5
PRISCILLA A. ERICKSON ET AL.
PAX
BP
RIB
EN
OB
P AX
BP
RIB
EN
OB
P AX
BP
RIB
EN
OB
PAX
BP
RIB
EN
OB
PAX
BP
RIB
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OB
PAX
BP
RIB
EN
OB
PAX
BP
RIB
EN
OB
PAX
BP
RIB
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OB
PAX
BP
RIB
EN
OB
PAX
BP
RIB
EN
OB
PAX
BP
RIB
EN
OB
PAX
BP
RIB
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OB
PAX
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EN
OB
PAX
BP
RIB
EN
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PAX
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PAX
BP
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EN
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BP
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1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
Genome-wide QTL Genome-wide + Suggestive
10-13Gain|Loss:
LOD:
raker
teeth
branchial
jaw
skullopercle
medianfin
pelvicspine
chr:
>163.7-7 13-167-10
DepthSLPlatesPSRPSLDS3DS2DS1OPWOPLFWALDLPMHPMLJWEBCB5CB4CB3CB2CB1BHDTP2DTP1VTPCR9CR8CR7CR6CR5CR4CR3CR2CR1C
15 242
18
2 68
A
11 159
15
5 8
14
19.429.94.3
24.2
2.9 5.6
0.6
Simulated QTL locations
Key: PAXB PRIB ENOBB
Figure 2. Overview of QTL. (A) Summary of QTL detected at a LOD 3.7 genome-wide significance threshold. Chromosomes 1–21 are
separated by vertical lines and numbered below. Within each chromosome, QTL for PAXB, PRIB, and ENOB (labeled on top) are indicated
from left to right. Trait categories are labeled at left and separated by horizontal lines; descriptions of phenotype abbreviations at right
can be found in Table S2. Color intensity indicates magnitude of LOD score (see key). Red colors indicate skeletal gain QTL (freshwater
allele confers more bone); blue colors indicate skeletal loss QTL (freshwater allele confers less bone). QTL in which the phenotypes of
homozygous genotypes do not differ by a Student’s t-test (P > 0.05) are shaded in gray. (B) Venn diagrams of simulated QTL overlap
(left), all genome-wide QTL overlap (middle), and all QTL including suggestive parallel QTL (right).
in 10,000 permutations of the data, Table 1). However, double
QTL were not significantly enriched in any population pair. All
three crosses had significantly fewer unique QTL than expected
by chance at a P < 0.05 significance level (98–99% of permu-
tations had equal or more unique QTL, respectively, Table 1).
Combined, these results suggest that strong selection on some
skeletal traits may drive genetic parallelism for the QTL that were
found to overlap in all three lakes, which then may result in a
concomitant dearth of double and unique QTL. Despite this find-
ing, the majority of detected QTL (57/100 QTL) were unique to
a single cross, suggesting that benthic adaptation also has a large
nonparallel component.
The number of overlapping QTL might be overcounted if
mutations are present that affect the development of skeletal ele-
ments belonging to more than one trait class. In total, four distinct
genomic regions contain triple QTL, which is still significant in
a modified permutation test that disallows multiple triple QTL in
the same genomic region (P = 0.001). Therefore, we still find
6 EVOLUTION 2016
REPEATABLE EVOLUTION IN BENTHIC STICKLEBACKS
2
3
4
5
MM MF FF MM MF FF MM MF FFChromosome 4 Genotype
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rsal
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ine
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gth
(m
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MM MF FF MM MF FF MM MF FFChromosome 4 Genotype
Pel
vic
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ine
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(m
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MM MF FF MM MF FF MM MF FFChromosome 21 Genotype
Pel
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(m
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40
MM MF FF MM MF FF MM MF FFChromosome 4 Genotype
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MM MF FF MM MF FF MM MF FFChromosome 7 Genotype
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Figure 3. Armor QTL identified in all three crosses at the genome-wide (LOD 3.7) significance level. Phenotypes for each trait are shown
for fish with MM, MF, or FF genotypes at the peak marker in each cross on the left, where M = marine allele and F = freshwater allele. For
all five QTL, the freshwater allele produces smaller or fewer skeletal elements. The LOD profiles of each QTL plotted relative to genetic
distance (cM) are shown in the middle. Since genetic distance varies between crosses, the position of each marker was scaled relative to
the total mean genetic length of the chromosome in all three crosses. Cartoon illustrations of armor phenotypes measured or counted
are on the right, with skeletal elements highlighted in purple. (A) Dorsal spine 1 length, chr. 4; (B) Left pelvic spine length, chr. 4; (C)
Lateral plate count, chr. 4; (D) Left pelvic spine length, chr. 21; (E) Lateral plate count, chr. 7. PAXB = green, PRIB = blue, ENOB = red. See
Table S4 for additional information about each QTL.
significant parallelism when we account for potential pleiotropy
on chromosomes 4 and 21. As a second, even more conservative,
control for the potential pleiotropy of QTL, we performed an ad-
ditional filtering in our simulations that allows a genomic position
to be covered by at most one skeletal QTL per cross, regardless of
trait (see supplemental methods). Although five genomic regions
contained a QTL affecting at least one trait in all three crosses,
neither double nor triple QTL were statistically significantly en-
riched relative to the expectations from these simulations (see
Table S6).
EVOLUTION 2016 7
PRISCILLA A. ERICKSON ET AL.
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Figure 4. Shared craniofacial QTL. QTL for gill raker number (chr. 4), ventral pharyngeal tooth number (chr. 21), and branchial bone
length (chr. 4 and chr. 21) have previously been described in PAXB × marine crosses (Cleves et al. 2014; Erickson et al. 2014; Glazer et al.
2014; Miller and Glazer et al. 2014). Phenotypes for each genotypic class at the peak marker are shown on the left (M = marine, F =freshwater). The LOD profiles of each QTL plotted relative to genetic distance (cM) are shown in the middle, as in Figure 3. Craniofacial
bones measured or counted are highlighted in purple to the right; images of flat-mounted branchial skeletons are shown with anterior
at top. Panels A, B and E show triple-overlapping QTL at the genome-wide threshold; C and D each include one suggestive parallel QTL.
(A) Ventral pharyngeal teeth, chr. 21; (B) All row 1–9 gill rakers, chr. 4; (C) Epibranchial 1 length, chr. 4; (D) Epibranchial 1 length, chr. 21;
(E) Opercle width, chr. 8. PAXB = green, PRIB = blue, ENOB = red.
We might fail to detect some overlapping QTL due to small
effect sizes that fail to meet the strict genome-wide LOD cutoff
(Beavis 1998). To test this possibility, we performed a second
search for QTL by looking for suggestive parallel QTL in the
regions of the genome where QTL had been identified in at least
one cross for the trait class. This analysis identified a total of 43
new suggestive QTL (13 PAXB, 13 PRIB, and 17 ENOB, Fig. S4,
Fig. S5, Table S5), including six new triple-overlapping QTL that
were not previously identified at the genome-wide significance
threshold (Fig. 2B, Table S9). We found that 68% and 71% of
8 EVOLUTION 2016
REPEATABLE EVOLUTION IN BENTHIC STICKLEBACKS
Table 1. Results of QTL overlap simulation.
Mean 2.5% 97.5% P (simulated �QTL type Observed simulated simulated simulated observed)
PAXB unique 18 24.2 19 29 0.9964PRIB unique 24 29.9 25 35 0.994ENOB unique 15 19.4 15 23 0.9826PAXB-PRIB overlapping 6 5.6 2 10 0.5014PAXB-ENOB overlapping 2 2.9 0 6 0.8149PRIB-ENOB overlapping 2 4.3 1 8 0.9477triple overlapping 8 0.6 0 2 <0.0001
The physical locations of the QTL were randomly permuted 10,000 times and tested for overlap between crosses in each permutation. The total number
of pairwise overlaps and triple overlaps was counted. The mean, 2.5 and 97.5 percentiles of permuted overlapping QTL are presented. The P-value was
calculated based on the number of permutations with an equal or greater number of overlaps than the actual observed overlaps. See Fig. S3 for the
distribution of simulated numbers of QTL overlaps.
the suggestive double-and triple-overlapping QTL, respectively,
had effects in the same direction. When these QTL are included,
67% of all QTL overlap with at least one other QTL, and 33%
are unique to a single cross. Thus, the relatively small sizes of our
crosses (�180 F2s) may have prevented us from detecting some
overlapping QTL, causing us to underestimate parallelism in the
main analysis.
MOST QTL ARE NOT SHARED BETWEEN LAKES
Despite the significant enrichment for overlap of genomic regions
influencing similar phenotypes in the three crosses, the majority
of QTL identified (57%) were not shared. Several striking nonpar-
allel genetic patterns were observed. For example, severe pelvic
reduction has been described in Paxton benthics, but not in Priest
or Enos benthics. Consistent with the previously described role of
Pitx1 in mediating pelvic reduction in PAXB fish (Shapiro et al.
2004; Chan et al. 2010), we detected a large effect QTL con-
trolling presence or absence of pelvic spines in the PAXB cross
that mapped to the end of chromosome 7 containing Pitx1 (Fig.
S6). Over half of all gill raker QTL (9/16) were unique to a sin-
gle cross, and of 13 QTL affecting branchial bone length, only
one double-overlapping QTL was observed at the genome-wide
significance cutoff.
WEAK RELATIONSHIP BETWEEN QTL EFFECT SIZE
AND PARALLELISM
We tested the prediction of Conte et al. (2015) that large ef-
fect QTL would be more likely to overlap in multiple benthic
populations than small effect QTL. Briefly, population genetics
theory predicts that evolution via new mutations or standing vari-
ation should produce a positive correlation between parallelism
and QTL effect size. We tested this prediction by examining the
relationship between the average PVE of each QTL within a
trait class and the number of overlaps for that QTL. Because
● ●●●
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0
20
40
60
80
1 2 3# Crosses containing QTL
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rag
e P
VE
Figure 5. Larger effect QTL overlap in multiple benthic crosses.
The highest PVE QTL controlling each trait class, including sugges-
tive QTL, was identified for each cross to reduce oversampling of
phenotypes with multiple QTL. QTL were classified as overlapping
in 1, 2, or 3 crosses based on overlap of the physical 1.5 LOD inter-
vals for QTL controlling the same trait category. For overlapping
QTL, the average PVE was calculated between crosses. Average
PVE is plotted against the number of crosses in which overlapping
QTL were found, and points are jittered along the x-axis to show
all points. A significant relationship between effect size and par-
allelism was observed (Spearman rank correlation, ρ = 0.50, n =20, P = 0.02).
traits with many small effect QTL might have QTL that over-
lap by chance, we restricted our analysis of PVE versus effect
size to only the largest effect QTL affecting each trait class in
each cross, to reduce oversampling of trait categories with many
QTL (as in Conte et al. 2015). Because small effect QTL are
less likely to be detected in parallel, we included suggestive QTL
if they were the largest effect QTL for the trait. We found a
significant relationship between PVE and effect size (ρ = 0.50,
n = 20, P = 0.02, Fig. 5), though this effect was driven by the
EVOLUTION 2016 9
PRISCILLA A. ERICKSON ET AL.
large effect, parallel QTL on chromosome 4. When we performed
this correlation analysis on the list of maximally filtered QTL
regions, to reduce oversampling of individual chromosomes, the
relationship was not significant (ρ = 0.139, n = 28, P = 0.49).
Therefore, our results confirm those of Conte et al. (2015)—the
relationship between parallelism and effect size is at most weak
and driven by a few QTL on the same chromosome.
BENTHIC QTL ARE CLUSTERED IN THE GENOME
In a previous PAXB × marine cross, three chromosomes (4, 20,
and 21) were enriched for QTL for the studied traits (Miller et al.
2014). We hypothesized that enrichment of QTL on these chro-
mosomes is a general feature of adaptation to freshwater benthic
environments. We tested for significant clustering of QTL in all
three crosses using a chi-square test and null expectations based
on physical length, genetic length, and Ensembl-predicted gene
number (using the revised assembly from Glazer et al. 2015).
We found that, by all three expectations, the PAXB cross was
enriched for QTL on chromosome 21, the PRIB cross was en-
riched for QTL on chromosomes 4 and 21, and the ENOB cross
was enriched for QTL on chromosome 4 (Table 2). Additionally,
enrichment for QTL on chromosomes 19 and 5 was seen in the
PRIB and ENOB crosses, respectively, for two of these three tests
of clustering. Therefore, two of the three previously identified
trait clusters were found in benthic populations other than PAXB
and had significantly clustered QTL on chromosomes when ac-
counting for chromosome genetic length, physical length, or gene
number. Interestingly, using the same chi-square test to compare
predicted gene number on each chromosome to its physical length
based on the revised genome assembly of Glazer et al. 2015, we
found that chromosomes 4 and 21 have significantly fewer genes
than expected based on their physical length (standard residuals
of –5.70 and –7.61, respectively). Despite this low gene number,
they have more QTL per unit physical length.
BENTHIC QTL ARE ENRICHED FOR GENOMIC
SIGNATURES OF NATURAL SELECTION
Next, we hypothesized that QTL important for benthic adaptation
would be enriched for loci showing signatures of natural selec-
tion in two analyses of stickleback divergence: marine-freshwater
(Jones et al. 2012b) and benthic-limnetic (Jones et al. 2012a).
These studies looked for genetic variants that were shared among
freshwater (or benthic) populations and differed from marine (or
limnetic) populations. We tested for enrichment by calculating
the number of selected loci overlapping with benthic skeletal
QTL compared to a randomly permuted set of QTL. We found
that shared QTL (double- and triple-overlapping) were enriched
for loci showing marine-freshwater signals of selection (P < 0.05,
Table 3). However, unshared QTL, those found in single lakes,
were not enriched (P = 0.18–0.54, Table 3). Shared QTL were
also enriched for a set of 46 SNPs found to have high FST in
at least one benthic-limnetic species pair (Jones et al. 2012a),
whereas the unshared, lake-specific QTL were not enriched (with
the exception of Paxton lake, which was slightly enriched, Table
3). When we included the suggestive parallel QTL in the analy-
sis, the results were similar, with double- and triple-overlapping
QTL enriched for both marine-freshwater and benthic-limnetic
signals of selection (Table S7). Thus, the overlapping genomic
regions underlying similar skeletal QTL are enriched for loci
showing population genetic signals of selection, suggesting these
genomic regions are under strong natural selection during benthic
adaptation.
MOST QTL DO NOT OVERLAP THREE PREVIOUSLY
IDENTIFIED INVERSIONS
Chromosomal inversions are theoretically predicted to contribute
to adaptation when there is gene flow and multiple loci with
selected alleles are found within the inversion (Kirkpatrick and
Barton 2006; Hoffmann and Rieseberg 2008). Supporting these
predictions, inversions contribute to evolved differences between
populations of butterflies, sparrows, and monkeyflowers (Thomas
et al. 2008; Lowry and Willis 2010; Joron et al. 2011; Fishman
et al. 2013; Kunte et al. 2014). In sticklebacks, three chromo-
somal inversions typically have different orientations in marine
and freshwater populations (Jones et al. 2012b). A total of 11
detected QTL overlap one of these three inversions, a significant
enrichment relative to QTL placed randomly in the genome (P =0.02, based on 10,000 permutations). This enrichment was driven
mainly by the QTL cluster on chromosome 21 (Fig. S5). We have
evidence that at least some of the QTL overlapping this inversion
genetically map outside of the inversion (see Discussion).
DiscussionPARALLEL QTL ARE ENRICHED, BUT THE MAJORITY
OF QTL ARE NONPARALLEL
The benthic-limnetic stickleback species pairs provide a power-
ful system to study ecological adaptation and incipient speciation
(Schluter and Rambaut 1996; Schluter 2001). One long-standing
question has been the extent of genetic parallelism underlying
the benthic and limnetic phenotypic convergence across lakes
(Schluter and Conte 2009; Schluter et al. 2010). Prior to this
study, the only study addressing the extent of genetic parallelism
underlying phenotypic convergence in this system used QTL map-
ping in benthic-limnetic crosses from two lakes containing species
pairs (Conte et al. 2015). Here, we significantly extend our under-
standing of the genetic basis of convergent adaptation by studying
the benthic ecotype from three lakes with species pairs and us-
ing a common marine genetic background. To our knowledge,
this study represents one of the first to use genome-wide linkage
1 0 EVOLUTION 2016
REPEATABLE EVOLUTION IN BENTHIC STICKLEBACKS
Table 2. Results of QTL clustering analyses.
By genes (Ensembl) By physical length (Mb) By genetic length (cM)
Cross P Enriched Chr. P Enriched Chr. P Enriched Chr.
PAXB 0.004 21 0.04 21 0.01 21PRIB 0.008 4, 19, 21 0.034 4, 19, 21 0.019 4, 21ENOB 0.008 4 0.018 4, 5 0.005 4, 5
A chi-square test was used to test whether the distribution of QTL across chromosomes was proportional to gene number (based on Ensembl predictions),
physical length (Mb), or genetic length (cM). P-values were based on 10,000 permutations of the data, and enriched chromosomes are chromosomes that
had standard residuals > 2 (as in Arnegard et al. 2014).
Table 3. Shared QTL are enriched for marine-freshwater and
benthic-limnetic genomic signals of selection.
Signals of selection:
Marine-freshwater Benthic-limnetic
QTL set:PAXB unique (n = 18) 1.36 (0.18) 1.85 (0.03)PRIB unique (n = 24) 1.15 (0.28) 1.34 (0.11)ENOB unique (n = 15) 0.88 (0.54) 0.99 (0.44)All double (n = 10) 2.24 (0.0011) 1.91 (0.002)All triple (n = 8) 3.59 (<0.0001) 2.35 (0.0006)
The number of overlaps between loci with signals of selection and benthic
QTL were counted and compared to 10,000 random permutations of the
QTL locations. Values given are the fold enrichment followed by the P-value
in parentheses. Marine-freshwater loci with signals of selection based on
Jones et al. 2012b and benthic-limnetic loci with signals of selection based
on Jones et al. 2012a.
mapping in three independently derived, convergently evolved
lineages to study the genetic basis of repeated adaptive diver-
gence.
We found that the genomic regions underlying benthic adap-
tation in three independently derived populations significantly
overlap, supporting the hypothesis of a parallel genetic compo-
nent to convergent skeletal evolution. We found that 47% (16/33)
of PAXB QTL, 40% (16/40) of PRIB QTL, and 44% (12/27) of
ENOB QTL overlapped a QTL affecting a similar phenotype in
at least one other benthic population. Furthermore, eight QTL un-
derlying similar phenotypes, accounting for 20–29% of all QTL
found in each cross, overlapped in all three populations, with 88%
having effects in the same direction in all three crosses. It is im-
portant to note that since all QTL identified here contain multiple
genes, finding overlapping QTL does not necessarily mean that
the underlying genes or genetic changes are the same. The ge-
netic resolution of these QTL is coarse (due to a small cross size
of �180 F2s per cross), and many QTL regions contain hundreds
of genes. These results suggest that some shared large genomic
regions repeatedly underlie benthic adaptation. However, only
identifying the actual genes underlying these evolved phenotypes
can answer the question of whether true genetic parallelism has
occurred.
Despite this uncertainty of whether QTL parallelism re-
flects genetic parallelism, observing nonoverlapping QTL is more
straightforward to interpret, as nonoverlapping QTL strongly sup-
port a nonparallel genetic basis. In this study, despite the signifi-
cant enrichment for overlapping QTL, 57% of all detected QTL
were found in only one population. This partially predictable
but largely nonparallel basis of convergent evolution is consistent
with previous findings that although 35% of divergent genomic re-
gions within a single marine-freshwater contrast were shared with
marine-freshwater divergence worldwide, 65% were not (Jones
et al. 2012a). Furthermore, our results of partially repeatable evo-
lution are consistent with the degree of genetic parallelism found
in a previous study of benthic and limnetic sticklebacks (Conte
et al. 2015) as well as a meta-analysis of parallelism in a wide
variety of organisms (Conte et al. 2012). Our results highlight a
remarkable outcome: benthic adaptation has occurred three times
via largely different genetic mechanisms. The largely nonparal-
lel genetic basis for dozens of phenotypes suggests that previous
findings on sticklebacks that identified a parallel genetic basis for
freshwater traits (Colosimo et al. 2004, 2005; Cresko et al. 2004;
Miller et al. 2007; Chan et al. 2010) are not representative of all
traits.
Our results showing a partially predictable genomic basis of
convergent evolution fit within a spectrum of previous work show-
ing both repeated and nonrepeated bases of convergent evolution
at the QTL level in diverse organisms. Three species of Mimulus
have all convergently evolved changes in leaf shape. In all three
species, leaf shape mapped to the same two genomic regions
(Ferris et al. 2015). Likewise, multiple populations of clinally
adapted Drosophila melanogaster share overlapping QTL for
wing size (Gockel et al. 2002; Calboli et al. 2003). However,
in D. simulans, similar clinal variation in wing size maps to one
genomic region that overlaps a melanogaster QTL and one dis-
tinct region (Lee et al. 2011). Similar to our finding, two strains of
weedy rice have adapted to the agricultural environment through
EVOLUTION 2016 1 1
PRISCILLA A. ERICKSON ET AL.
nonoverlapping QTL for three traits, but partially overlapping
QTL for a fourth trait (Thurber et al. 2013). Thus our work adds
to a growing list of partial parallelism at the QTL level, sug-
gesting that the same genomic regions only sometimes underlie
convergent adaptation, and enabling future work to test genetic
parallelism.
PLEIOTROPY, QTL CLUSTERING, AND INVERSIONS
Pleiotropic loci influencing multiple adaptive phenotypes have
been observed in monkeyflowers, rice, flies, and mice (Hall et al.
2006; Yan et al. 2011; Linnen et al. 2013; Paaby et al. 2014) and
could explain the multiple triple-overlapping QTL found on chro-
mosome 4. The peak marker and 1.5 LOD intervals were highly
similar for the chromosome 4 pelvic and dorsal spine length QTL
within each cross, and both overlapped a gill raker QTL and the
previously described Eda lateral plate QTL (Colosimo et al. 2004,
2005), which was found in all three crosses. Parsimoniously, a
shared locus with pleiotropic effects could underlie all four phe-
notypes in benthic populations. Although the Eda haplotype that
controls lateral plates has not been reported to affect gill raker or
spine morphology, Eda mRNA expression is observed in dorsal
and pelvic spine tissue (Colosimo et al. 2004, 2005; O’Brown
et al. 2015), Eda receptor expression is detected in forming gill
raker buds (Glazer et al. 2014), and zebrafish Eda mutants lack
dorsal fins, pelvic fins, and gill rakers (Harris et al. 2008). How-
ever, in PRIB, the dorsal spine QTL does not overlap Eda, and
in PAXB, the gill raker QTL does not overlap any other QTL,
suggesting these traits are affected by separate tightly linked loci.
Thus, we hypothesize chromosome 4 has at least two armor re-
duction loci (Eda plus at least one spine length locus), as well as a
gill raker reduction locus, that form a skeletal reduction supergene
(Schwander et al. 2014). Identifying the genes underlying these
QTL and testing whether freshwater alleles are in linkage dise-
quilibrium with the low-armor Eda allele in marine fish could test
this hypothesis. These results combined with the overall genomic
clustering of QTL suggest an important role for pleiotropic QTL
and/or supergenes as drivers of parallel adaptation in benthic en-
vironments. Approaches to infer pleiotropy in QTL studies have
been developed (Jiang and Zeng 1995), which future analyses
could apply to correlated traits in sticklebacks.
Like previous studies, (Arnegard et al. 2014; Liu et al. 2014;
Miller et al. 2014) we mapped multiple QTL to chromosomes
4 and 21 in some crosses. Unlike Miller et al. (2014), we did
not identify a chromosome 20 QTL cluster, perhaps because the
PAXB grandparent used in this cross and the grandparent used in
the previous cross had different chromosome 20 alleles. Addition-
ally, the relatively smaller sizes of our cross and reduced number
of phenotypes scored may have prevented us from detecting some
loci that contribute to clustering (e.g., we did not phenotype sev-
eral bones that were part of the cluster found in Miller et al. 2014).
Furthermore, because clustering was seen when we adjusted for
genetic length, physical length, or gene number, clustering does
not appear to result simply from recombination suppression or
differential gene density between chromosomes.
Theoretical work has proposed that inversions could evolve
because they cluster adaptive loci and prevent their recombination
(Kirkpatrick and Barton 2006; Hoffmann and Rieseberg 2008). In
sticklebacks, inversions on chromosomes 1, 11, and 21 are oppo-
sitely fixed in most marine and freshwater populations including
the PAXB population (Jones et al. 2012b). These three inversions
were significantly enriched within detected QTL intervals, in-
cluding two triple QTL and two double QTL on chromosome 21.
However, in the PAXB population, tooth number fine-maps to a
genomic interval over a megabase outside of the inversion (Cleves
et al. 2014), so the triple-overlapping tooth number QTL is likely
not in the inversion. Likewise, the PAXB pelvic spine length QTL
also maps entirely outside the inversion, so the triple-overlapping
pelvic spine length QTL is also unlikely to be in the inversion.
Chromosome 4, highly enriched for QTL and triple-overlapping
QTL, does not contain one of these inversions. Therefore, al-
though a few QTL could be due to mutations within inversions,
most QTL involved in benthic skeletal adaptation (at least 89/100,
since only 11/100 QTL overlap one of these three inversions) do
not map to these three previously described inversions.
SHARED QTL AND FRESHWATER ADAPTATION
Many of the triple QTL we identified have been found in previous
studies, but little was known about their parallelism. A chromo-
some 4 gill raker reduction QTL was found in three freshwater
populations (Glazer et al. 2014) and was detected in all three
benthic populations here. A chromosome 21 tooth QTL maps to
a cis-regulatory allele of the Bmp6 gene in the PAXB popula-
tion (Cleves et al. 2014), and the presence of a similar tooth gain
QTL in two other benthic populations suggests that increased
tooth number is adaptive in benthic environments. Chromosomes
4 and 21 also increase branchial bone length in multiple freshwa-
ter populations (Erickson et al. 2014), and each QTL was found
in a second benthic population, suggesting increased branchial
bone length may also be adaptive. Continued mapping of these
QTL will help determine whether the parallelism we observe is
due to different tightly linked genes, different mutations in the
same gene, or repeated selection of standing variants. Given the
geographic proximity of the lakes, we hypothesize that common
shared ancestral alleles underlie the shared QTL, whereas QTL
unique to a single cross are due to rarer ancestral variants or new
mutations.
Genomic techniques such as RAD-seq and genome sequenc-
ing have enabled the discovery of local and temporal genomic
signatures of selection in a variety of organisms including maize
(Hufford et al. 2012), monkeyflowers (Stankowski and Streisfeld
1 2 EVOLUTION 2016
REPEATABLE EVOLUTION IN BENTHIC STICKLEBACKS
2015), flies (Bergland et al. 2014), stick insects (Soria-Carrasco
et al. 2014), wolves (Schweizer et al. 2015), cichlids (Ford et al.
2015), whitefish (Laporte et al. 2015), salmon (Seeb et al. 2014),
and sheep (Kardos et al. 2015). However, an understanding of the
phenotypes underlying these regions is often far more limited.
QTL mapping of diverse phenotypes that differ between popula-
tions can provide a starting point to connect genomic signatures
of selection to loci affecting morphology and physiology. We
found that overlapping QTL were strongly enriched for genomic
signatures of recurrent natural selection in multiple freshwater
populations (Jones et al. 2012b). Importantly, these genomic re-
gions are divergent in multiple freshwater and marine popula-
tions, so the QTL enrichment in these regions may be related to
skeletal changes involved in general freshwater adaptation, rather
than benthic adaptation. However, shared QTL were also enriched
for SNPs that are FST outliers between limnetic and benthic fish
(Jones et al. 2012a), suggesting some of the QTL might underlie
benthic adaptation. Whether the QTL we identified are due to ge-
netic variants that drive these signals of selection or whether the
QTL are hitchhiking along with other loci important for freshwa-
ter adaptation remains currently unknown. However, the signals
of selection can pinpoint interesting candidate genes for the QTL
intervals, which ultimately could link these population genetic
signals of selection to adaptive phenotypes.
ACKNOWLEDGMENTSWe thank Chris Martin for helpful suggestions on data analysis. Thiswork was supported in part by NIH R01 #DE021475 (C.M.), an NIHPredoctoral Training Grant #5T32GM007127 (P.E.), NSF Graduate Re-search Fellowships (A.G. and P.C.), and Discovery grants from the Nat-ural Sciences and Engineering Research Council of Canada (D.S.). Thiswork used the Vincent J. Coates Genomics Sequencing Laboratory at UCBerkeley, supported by NIH S10 Instrumentation Grants S10RR029668and S10RR027303.
DATA ARCHIVINGAll sequence reads are deposited in the Sequence Read Archive (accessionnumber SRP070856).
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Associate Editor: L. FishmanHandling Editor: R. Shaw
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Supporting InformationAdditional Supporting Information may be found in the online version of this article at the publisher’s website:
Supplementary MethodsFigure S1. Correlation matrix of all raw phenotypes measured.Figure S2. Distribution of QTL effect sizes.Figure S3. Results of QTL overlap simulations.Figure S4. Overview of all suggestive parallel QTL relative to genome-wide QTL.Figure S5. Location of all filtered QTL.Figure S6. Pelvic spine presence/absence maps to chromosome 7 in PAXB.Table S1. Description of F2 families included in analysis.Table S2. Statistical corrections applied to each phenotype in each F2 family.Table S3. Data for processing of Illumina reads into genotypes for 3 crosses.Table S4. (.xlsx file) All QTL detected at genome wide LOD cutoff (3.7).Table S5. (.xlsx file) All QTL including suggestive QTL.Table S6. Results of QTL overlap simulations without respect to QTL category.Table S7. Shared suggestive QTL are enriched for marine-freshwater and benthic-limnetic signals of selection.Table S8. (.xlsx file) Locations of all double and triple QTL detected at genome-wide cutoff.Table S9. (.xlsx file) Locations of all double and triple QTL detected including suggestive QTL.Supplemental File 1. (.xlsx file) All data used for QTL mapping.
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